Expression of the tumor antigens NY-ESO-1, tyrosinase, MAGE-A3, and TPTE in pediatric and adult melanoma: a retrospective case control study.

Tumor-associated antigens (TAAs) are potential targets for T cell-based immunotherapy approaches in cutaneous melanoma. BNT111, an investigational lipoplex-formulated mRNA-based therapeutic cancer vaccine encoding melanoma TAAs NY-ESO-1, tyrosinase, MAGE-A3, and TPTE, is undergoing clinical testing in adults. Expression of these TAAs in pediatric melanoma is unclear but is a prerequisite for feasibility of this treatment approach in children with melanoma. Our main objective was to characterize expression of those TAAs in pediatric melanomas compared to control cohorts. In this retrospective case control study, protein and transcript expression of NY-ESO-1, tyrosinase, MAGE-A3, and TPTE were analyzed in a cohort of 25 pediatric melanomas, 31 melanomas of young adults, 29 adult melanomas, and 30 benign melanocytic nevi in children using immunohistochemical staining and digital pathology (QuPath) and reverse transcription quantitative PCR. Based on IHC analysis, pediatric melanomas expressed tyrosinase (100.0%), TPTE (44.0%), MAGE-A3 (12.0%), and NY-ESO-1 (8.0%). Young adult melanomas expressed tyrosinase (96.8%), NY-ESO-1 (19.4%), MAGE-A3 (19.4%), and TPTE (3.2%). Adult melanomas expressed tyrosinase (86.2%), MAGE-A3 (75.9%), NY-ESO-1 (48.3%), and TPTE (48.3%). Childhood melanocytic nevi only expressed tyrosinase (93.3%). Expression prevalence of individual TAAs did not differ between subtypes of pediatric melanoma, and no association with prognosis was found. All four TAAs were expressed in pediatric melanoma, albeit NY-ESO-1 and MAGE-A3 to a lesser extent than in adult melanoma. These data support the possibility of investigating vaccines targeting these TAAs for the treatment of pediatric melanoma.

Common fragile sites and cancer: targeted cloning by insertional mutagenesis.

Genetic instability is an important facet of carcinogenesis and oncogenesis, generating chromosomal variability and extensive intratumor heterogeneity. Common fragile sites are predetermined chromosomal breakage regions. Experimentally, they can be demonstrated as site-specific gaps or breaks seen on metaphase chromosomes under conditions of replicative stress. They have been known for many years as a chromosomal expression of genetic instability and have been implicated to have a causative role in cancer. However, common fragile sites still remain enigmatic intrinsic parts of human chromosomes, and the DNA sequences at most of the fragile sites have not been identified so far. The idea of genetically tagging fragile site DNA by insertional mutagenesis through an exogenous marker gene has provided a platform for the efficient targeted cloning of a substantial number of common fragile sites.

Immunogenicity and its impact on benefit/risk considerations in the authorisation of biopharmaceuticals.

Antibody formation is an intended physiological reaction to a "non-self" protein intentionally triggered in the case of vaccines. However, an unwanted immune response to a therapeutic protein may lead to a loss of efficacy and/or to severe side effects. The Committee for Medicinal Products for Human Use (CHMP) at the European Medicines Agency (EMA) issued a multidisciplinary guideline providing general recommendations from a marketing authorisation perspective on how to systematically assess an unwanted immune response following the administration of a biological drug. In this article, we discuss key aspects of this guideline and its concept, with a particular focus on the impact of immunogenicity on benefit/risk estimation of a therapeutic protein.